Display driver and semiconductor device

Abstract

A display driver includes a gamma correction data transmission unit that transmits a plurality of gamma correction data pieces one by one in each predetermined period. A brightness level indicated by a video signal is converted into a gradation voltage with a gamma characteristic based on the gamma correction data piece transmitted from the gamma correction data transmission unit.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a display driver for driving a display panel and a semiconductor device in which the display driver is provided.

2. Description of the Related Art

Display drivers for driving a display panel such as a liquid crystal display panel and an organic EL display panel generate gradation voltages corresponding to brightness levels of respective errors indicated by input video signals, and apply the gradation voltages to respective source lines of the display panels as pixel drive voltages. The display drivers perform gamma correction to correct the correspondence relation between brightness indicated by the input video signal and brightness actually displayed on the display panel, in each of red, green, and blue colors.

As such a display driver that performs the gamma correction, there is proposed one that includes three systems of gradation voltage conversion circuits. The three systems of gradation voltage conversion circuits include three systems of registers to store set values for the gamma correction on a color-by-color (red, green, and blue) basis, and convert display data into gradation voltages on a color-by-color (red, green, and blue) basis in accordance with characteristics based on the set values stored in the registers (for example, see Patent Document 1: Japanese Patent Application Laid-Open No. 2012-137783).

SUMMARY OF THE INVENTION

By the way, the gradation voltage conversion circuit includes, in addition to the aforementioned registers, a ladder resistor to generate a reference gradation voltage corresponding to each gradation in accordance with the set value stored in the register, and an amplifier to output the voltage.

Accordingly, the display driver needs to have the three systems of gradation voltage conversion circuits (including the registers, the ladder resistors, and the amplifiers) corresponding to respective colors, thus causing an increase in the area of the gradation voltage conversion circuit in a chip and hence an increase in the size of the display driver.

Therefore, an object of the present invention is to provide a display driver that can be reduced in size, and a semiconductor device in which the display driver is formed.

According to one aspect of the present invention, a display driver supplies a display device having a plurality of display cells with gradation voltages corresponding to the brightness levels of the respective display cells indicated by a video signal. The display driver includes a gamma correction data transmission unit for transmitting a plurality of gamma correction data pieces representing gamma correction values one by one in each predetermined period, and a gradation voltage conversion unit for converting the brightness levels into the gradation voltages with a gamma characteristic based on the gamma correction value indicated by the gamma correction data piece transmitted from the gamma correction data transmission unit.

According to another aspect of the present invention, a semiconductor device includes a display driver that is formed therein and supplies a display device having a plurality of display cells with gradation voltages corresponding to the brightness levels of the respective display cells indicated by a video signal. The display driver includes a gamma correction data transmission unit for transmitting a plurality of gamma correction data pieces representing gamma correction values one by one in each predetermined period, and a gradation voltage conversion unit for converting the brightness levels into the gradation voltages with a gamma characteristic based on the gamma correction value indicated by the gamma correction data piece transmitted from the gamma correction data transmission unit.

According to one aspect of the present invention, the display driver is provided with the gamma correction data transmission unit that transmits the plurality of gamma correction data pieces one by one in each predetermined period. The gradation voltage conversion unit converts the brightness levels indicated by the video signal into the gradation voltages with the gamma characteristic based on the gamma correction data piece transmitted from the gamma correction data transmission unit.

According to such a configuration, the display driver just has only one system of gradation voltage conversion unit, irrespective of the number of types of gamma characteristics. Therefore, it is possible to reduce the size of the circuit, as compared with a configuration in which, for example, three systems of gradation voltage conversion units for each of three types of gamma characteristics corresponding to red, green, and blue colors are provided to convert brightness levels into gradation voltages with the gamma characteristics.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing a schematic configuration of a display apparatus 100 including a display driver according to the present invention;

FIG. 2 is a time chart showing an example of the format of an image data signal VDX and an example of the internal operation of a gradation voltage conversion unit 132;

FIG. 3 is a block diagram showing the internal configuration of a data driver 13;

FIG. 4 is a block diagram showing the internal configuration of a γ-correction data transmission unit 130 and the gradation voltage conversion unit 132;

FIG. 5 is a circuit diagram showing an example of the internal configuration of a reference gradation voltage generation circuit 32 (33);

FIG. 6 is a time chart showing another example of the format of the image data signal VDX and the operations of γ registers and selectors included in the reference gradation voltage generation circuit 32 (33); and

FIG. 7 is a circuit diagram showing another example of the internal configuration of the γ-correction data transmission unit 130.

FIG. 8 is a block diagram showing another configuration of the display apparatus 100 including the display driver according to the present invention;

FIG. 9 is a time chart showing an example of the format of an image data signal VDX and an example of the internal operation of a gradation voltage conversion unit 132A in the display apparatus 100 shown in FIG. 8;

FIG. 10 is a time chart showing an example of application timing of scan pulses DSP to data lines D₁ to D_n;

FIG. 11 is a block diagram showing the internal configuration of a data driver 13A; and

FIG. 12 is a block diagram showing the internal configuration of a γ-correction data transmission unit 130A and the gradation voltage conversion unit 132A.

DETAILED DESCRIPTION OF THE INVENTION

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a block diagram showing the schematic configuration of a display apparatus 100 including a display driver according to the present invention. In FIG. 1, a display device 20 is constituted by, for example, a liquid crystal display panel, and includes m (m is a natural number of 2 or more) horizontal display lines S₁ to S_m extending in a horizontal direction of a two-dimensional screen and n (n is an even number of 2 or more) data lines D₁ to D_n extending in a vertical direction of the two-dimensional screen. At each of intersections between each horizontal display line and each data line, a display cell C_R for red display, a display cell C_G for green display, or a display cell C_B for blue display is formed.

In the display device 20, as shown in FIG. 1, the display cell C_R is formed at each of the intersections between the horizontal display line S₁ and the data lines D₁ to D_n. The display cell C_G is formed at each of the intersections between the horizontal display line S₂ and the data lines D₁ to D_n. The display cell C_B is formed at each of the intersections between the horizontal display line S₃ and the data lines D₁ to D_n. The display cell C_R is formed at each of the intersections between the horizontal display line S₄ and the data lines D₁ to D_n. The display cell C_G is formed at each of the intersections between the horizontal display line S₅ and the data lines D₁ to D_n. The display cell C_B is formed at each of the intersections between the horizontal display line S₆ and the data lines D₁ to D_n.

In other words, the horizontal display lines S_(3r−2) (r is natural numbers) are red display lines in each of which n display cells C_R for red display are arranged. The horizontal display lines S_(3r−1) are green display lines in each of which n display cells C_G for green display are arranged. The horizontal display lines S_(3r) are blue display lines in each of which n display cells C_B for blue display are arranged.

A drive control unit 11 generates an image data signal VDX in a format of FIG. 2 based on a video signal VD.

In other words, the drive control unit 11 first calculates display data PD that represents a brightness level of each display cell (C_R, C_G, C_B) as, for example a 256-step brightness gradation of 8 bits, on the basis of the video signal VD. Next, the drive control unit 11 groups 3·n pieces of display data PD corresponding to three horizontal display lines of every three horizontal display lines S adjoining to each other on a color-by-color basis. In other words, the drive control unit 11 groups the 3·n pieces of display data PD into a display data series LD_R including the display data PD₁ to PD_n corresponding to the red display cells C_R, a display data series LD_G including the display data PD₁ to PD_n corresponding to the green display cells C_G, and a display data series LD_B including the display data PD₁ to PD_n corresponding to the blue display cells C_B.

The drive control unit 11, as shown in FIG. 2, generates the image data signal VDX in which the display data series LD_R corresponding to red are arranged in (3r−2)th horizontal scan periods H, the display data series LD_G corresponding to green are arranged in (3r−1)th horizontal scan periods H, and the display data series LD_B corresponding to blue are arranged in (3r)th horizontal scan periods H. Furthermore, the drive control unit 11 arranges γ-correction data, which is used when displaying each display data series (LD_R, LD_G, LD_B), for each horizontal scan period H of the image data signal VDX.

In other words, as shown in FIG. 2, positive γ-correction data PG_R and negative γ-correction data NG_R each representing γ-correction values for a red component are arranged in the horizontal scan period H having the display data series LD_R in the image data signal VDX. Positive γ-correction data PG_G and negative γ-correction data NG_G each representing γ-correction values for a green component are arranged in the horizontal scan period H having the display data series LD_G in the image data signal VDX. Positive γ-correction data PG_B and negative γ-correction data NG_B each representing γ-correction values for a blue component are arranged in the horizontal scan period H having the display data series LD_B in the image data signal VDX. The γγ-correction data (PG_R, NG_R, PG_G, NG_G, PG_B, NG_B) represents information corresponding to γ-correction values that are used when converting the display data PD into gradation voltages. To be more specific, the γ-correction data represents information for designating, out of nodes (called output taps below) between resistors in ladder resistors (described later), a plurality of output taps, for example, five output taps to perform a conversion corresponding to the γ-correction values.

The drive control unit 11 supplies the image data signal VDX generated as described above to a data driver 13. Furthermore, whenever the drive control unit 11 detects a horizontal synchronization signal from the video signal VD, the drive control unit 11 supplies a horizontal synchronization detection signal to a scan driver 12.

The scan driver 12 sequentially applies scan pulses to each of the horizontal display lines S₁ to S_m of the display device 20 in synchronous timing with the horizontal synchronization detection signal.

The data driver 13 is formed in a semiconductor IC (integrated circuit) chip.

FIG. 3 is a block diagram showing the internal configuration of the data driver 13. As shown in FIG. 3, the data driver 13 has a γ-correction data transmission unit 130, a data capture unit 131, a gradation voltage conversion unit 132, and an output unit 133.

The γ-correction data transmission unit 130 extracts the positive γ-correction data PG_R, PG_G, or PG_B from the image data signal VDX, and supplies the extracted positive γ-correction data to the gradation voltage conversion unit 132 as γ-correction data SP. The γ-correction data transmission unit 130 also extracts the negative γ-correction data NG_R, NG_G, or NG_B from the image data signal VDX, and supplies the extracted negative γ-correction data to the gradation voltage conversion unit 132 as γ-correction data SN.

The data capture unit 131 sequentially captures the display data PD₁ to PD_n constituting the display data series (LD_R, LD_G, LD_B) from the image data signal VDX for each horizontal scan period H, and supplies the n pieces of display data PD₁ to PD_n to the gradation voltage conversion unit 132 as display data Q₁ to Q_n.

The gradation voltage conversion unit 132 converts the display data Q₁ to Q_n into analog positive gradation voltages P₁ to P_n, respectively, with a conversion characteristic based on the positive γ-correction data (PG_R, PG_G, PG_B) included in the image data signal VDX. Furthermore, the gradation voltage conversion unit 132 converts the display data Q₁ to Q_n into analog negative gradation voltages N₁ to N_n, respectively, with a conversion characteristic based on the negative γ-correction data (NG_R, NG_G, NG_B) included in the image data signal VDX. The gradation voltage conversion unit 132 supplies the gradation voltages P₁ to P_n and N₁ to N_n to the output unit 133.

The output unit 133 selects one of each of the positive gradation voltages P₁ to P_n and each of the negative gradation voltages N₁ to N_n in an alternate manner at established intervals, and supplies the selected gradation voltages to the data lines D₁ to D_n of the display device 20 as gradation voltages G₁ to G_n.

FIG. 4 is a block diagram showing an example of the internal configuration of the γ-correction data transmission unit 130 and the gradation voltage conversion unit 132. As shown in FIG. 4, the γ-correction data transmission unit 130 includes a γ-correction data extraction circuit 21, a γ register 22, a γ-correction data extraction circuit 23, and a γ register 24.

The γ-correction data extraction circuit 21 extracts positive γ-correction data PG_R, PG_G, or PG_B from an image data signal VDX, and supplies the extracted positive γ-correction data PG_R, PG_G, or PG_B to the γ register 22 in each horizontal scan period H. The γ register 22 writes over previous data and holds the positive γ-correction data PG_R, PG_G, or PG_B supplied by the γ-correction data extraction circuit 21. The γ register 22 transmits the one piece of γ-correction data, which is held as described above, of the γ-correction data PG_R, PG_G, and PG_B to the gradation voltage conversion unit 132 over the one horizontal scan period H as positive γ-correction data SP.

The γ-correction data extraction circuit 23 extracts negative γ-correction data NG_R, NG_G, or NG_B from the image data signal VDX, and supplies the extracted negative γ-correction data NG_R, NG_G, or NG_B to the γ register 24 in each horizontal scan period H. The γ register 24 writes over previous data and holds the negative γ-correction data NG_R, NG_G, or NG_B supplied by the γ-correction data extraction circuit 23. The γ register 24 transmits the one piece of γ-correction data, which is held as described above, of the γ-correction data NG_R, NG_G, and NG_B to the gradation voltage conversion unit 132 over the one horizontal scan period H as negative γ-correction data SN.

According to the configuration as described above, the γ-correction data transmission unit 130 transmits the γ-correction data pieces PG_R, PG_G, and PG_B to the gradation voltage conversion unit 132 one by one for each horizontal scan period H. The γ-correction data transmission unit 130 also transmits the γ-correction data pieces NG_R, NG_G, and NG_B to the gradation voltage conversion unit 132 one by one for each horizontal scan period H.

The gradation voltage conversion unit 132 includes reference gradation voltage generation circuits 32 and 33, and DA conversion circuits 34 and 35.

Each of the reference gradation voltage generation circuits 32 and 33 has voltage setting terminals T1 to T3 and output terminals U1 to U256 to output reference gradation voltages of 256 steps.

The reference gradation voltage generation circuit 32 is supplied with set voltages VG1 to VG3, which have the following magnitude relations of voltage values, through the voltage setting terminals T1 to T3 of itself.
VG1>VG2>VG3

The reference gradation voltage generation circuit 32 generates 256-step positive reference gradation voltages Y1 to Y256 having difference voltage values to each other on the basis of the set voltages VG1 to VG3, and supplies the positive reference gradation voltages Y1 to Y256 to the DA conversion circuit 34.

The reference gradation voltage generation circuit 33 is supplied with set voltages VG3 to VG5, which have the following magnitude relations of voltage values, through the voltage setting terminals T1 to T3 of itself.
VG3>VG4>VG5

The reference gradation voltage generation circuit 33 generates 256-step negative reference gradation voltages X1 to X256 having difference voltage values to each other on the basis of the set voltages VG3 to VG5, and supplies the negative reference gradation voltages X1 to X256 to the DA conversion circuit 35.

The DA conversion circuit 34 selects a reference gradation voltage that corresponds to a brightness gradation represented by display data Q of each piece of the display data Q₁ to Q_n supplied by the data capture unit 131, from the positive reference gradation voltages Y1 to Y256. The DA conversion circuit 34 outputs each of the gradation voltages Y, which are selected for each piece of the display data Q₁ to Q_n as described above, as positive gradation voltages P₁ to P_n.

The DA conversion circuit 35 selects a reference gradation voltage that corresponds to a brightness gradation represented by display data Q of each piece of the display data Q₁ to Q_n supplied by the data capture unit 131, from the negative reference gradation voltages X1 to X256. The DA conversion circuit 35 outputs each of the gradation voltages X, which are selected for each piece of the display data Q₁ to Q_n as described above, as negative gradation voltages N₁ to N_n.

FIG. 5 is a circuit diagram showing the internal configuration of each of the reference gradation voltage generation circuits 32 and 33. Note that, the reference gradation voltage generation circuits 32 and 33 have the same circuit configuration. Each of the reference gradation voltage generation circuits 32 and 33 includes input amplifiers AMP1 and AMP2, a first ladder resistor (RD0 to RD160), a γ characteristic regulation circuit SX, output amplifiers AP0 to AP6, and a second ladder resistor (R0 to R254).

The first ladder resistor has resistors RD0 to RD160 connected in series. Output taps a1 to a160, which are nodes of the resistors RD0 to RD160, are connected to the γ characteristic regulation circuit SX. Note that, to the midpoint output tap a81 of the output taps a1 to a160, the voltage setting terminal T2 is connected.

The input amplifier AMP1 amplifies a voltage received at the voltage setting terminal T1 with a gain of 1, and supplies the amplified voltage through a line L0 to one end of the first resistor RD0 of the first ladder resistor and the output amplifier AP0. The input amplifier AMP2 amplifies a voltage received at the voltage setting terminal T3 with a gain of 1, and supplies the amplified voltage through a line L6 to one end of the last resistor RD160 of the first ladder resistor and the output amplifier AP6.

The γ characteristic regulation circuit SX connects five output taps that correspond to a γ-correction value represented by γ-correction data SP (SN) supplied by the γ-correction data transmission unit 130, in other words, five output taps of the output taps a1 to a160 of the first ladder resistor to lines L1 to L5, respectively. Note that, the line L1 is connected to an input terminal of the output amplifier AP1, and the line L2 is connected to an input terminal of the output amplifier AP2. The line L3 is connected to an input terminal of the output amplifier AP3, the line L4 is connected to an input terminal of the output amplifier AP4, and the line L5 is connected to an input terminal of the output amplifier AP5. For example, the γ characteristic regulation circuit SX connects, out of the five output taps that correspond to the γ-correction value represented by the γ-correction data SP (SN), the first output tap to the line L1, the second output tap to the line L2, and the third output tap to the line L3. Moreover, the γ characteristic regulation circuit SX connects the fourth output tap of the five output taps that correspond to the γ-correction value represented by the γ-correction data to the line L4, and connects the fifth output tap to the line L5.

The second ladder resistor has resistors R0 to R254 connected in series. The output terminal U1 is connected to one end of the first resistor R0 of the resistors R0 to R254, and the output terminal U256 is connected to one end of the last resistor R254. Furthermore, as shown in FIG. 5, the output terminals U2 to U255 are connected to nodes of the resistors R0 to R254 connected in series, respectively.

The output amplifier AP0 amplifies a voltage of the line L0 with a gain of 1, and supplies the amplified voltage to one end of the resistor R0 and the output terminal U1. The output amplifier AP1 amplifies a voltage of the line L1 with a gain of 1, and supplies the amplified voltage to the node between the resistors R0 and R1 and the output terminal U2. The output amplifier AP2 amplifies a voltage of the line L2 with a gain of 1, and supplies the amplified voltage to the node between the resistors R30 and R31 and the output terminal U31. The output amplifier AP3 amplifies a voltage of the line L3 with a gain of 1, and supplies the amplified voltage to the node between the resistors R126 and R127 and the output terminal U127. The output amplifier AP4 amplifies a voltage of the line L4 with a gain of 1, and supplies the amplified voltage to the node between the resistors R214 and R215 and the output terminal U215. The output amplifier AP5 amplifies a voltage of the line L5 with a gain of 1, and supplies the amplified voltage to the node between the resistors R253 and R254 and the output terminal U255. The output amplifier AP6 amplifies a voltage of the line L6 with a gain of 1, and supplies the amplified voltage to one end of the resistor R254 and the output terminal U256.

According to the configuration of FIG. 5, the reference gradation voltage generation circuit 32 (33) generates the reference gradation voltages Y1 to Y256 (X1 to X256) having a γ characteristic based on the γ-correction data SP (SN) supplied by the γ-correction data transmission unit 130, and supplies the reference gradation voltages Y1 to Y256 (X1 to X256) to the DA conversion circuit 34 (35) through the output terminals U1 to U256.

The operation of the configuration shown in FIGS. 4 and 5 will be described below with reference to FIG. 2.

First, in a horizontal scan period CY1 of an image data signal VDX in which a display data series LD_R is arranged, as shown in FIG. 2, the γ-correction data extraction circuit 21 of the γ-correction data transmission unit 130 extracts positive γ-correction data PG_R arranged in the head portion thereof from the image data signal VDX, and supplies the positive γ-correction data PG_R to the γ register 22. In the horizontal scan period CY1, the γ-correction data extraction circuit 23 of the γ-correction data transmission unit 130 extracts negative γ-correction data NG_R arranged in the head portion thereof from the image data signal VDX, and supplies the negative γ-correction data NG_R to the γ register 24. Thus, as shown in FIG. 2, the γ register 22 supplies the γ-correction data PG_R to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 32 as γ-correction data SP, while holding the γ-correction data PG_R. Also, as shown in FIG. 2, the γ register 24 supplies the γ-correction data NG_R to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 33 as γ-correction data SN, while holding the γ-correction data NG_R.

Thus, the reference gradation voltage generation circuit 32 generates reference gradation voltages Y1 to Y256 having a γ characteristic based on the γ-correction data PG_R, and supplies the reference gradation voltages Y1 to Y256 to the DA conversion circuit 34. The reference gradation voltage generation circuit 33 generates reference gradation voltages X1 to X256 having a γ characteristic based on the γ-correction data NG_R, and supplies the reference gradation voltages X1 to X256 to the DA conversion circuit 35. The DA conversion circuit 34 converts display data Q₁ to Q_n corresponding to the aforementioned display data series LD_R into analog positive gradation voltages P₁ to P_n, respectively, on the basis of the reference gradation voltages Y1 to Y256 having the γ characteristic based on the γ-correction data PG_R. The DA conversion circuit 35 converts display data Q₁ to Q_n corresponding to the aforementioned display data series LD_R into analog negative gradation voltages N₁ to N_n, respectively, on the basis of the reference gradation voltages X1 to X256 having the γ characteristic based on the γ-correction data NG_R.

Next, in a horizontal scan period CY2 of the image data signal VDX in which a display data series LD_G is arranged, as shown in FIG. 2, the γ-correction data extraction circuit 21 extracts positive γ-correction data PG_G arranged in the head portion thereof from the image data signal VDX, and supplies the positive γ-correction data PG_G to the γ register 22. In the horizontal scan period CY2, the γ-correction data extraction circuit 23 extracts negative γ-correction data NG_G arranged in the head portion thereof from the image data signal VDX, and supplies the negative γ-correction data NG_G to the γ register 24. Thus, as shown in FIG. 2, the γ register 22 supplies the γ-correction data PG_G to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 32 as γ-correction data SP, while writing over the previous data and holding the γ-correction data PG_R. Also, as shown in FIG. 2, the γ register 24 supplies the γ-correction data NG_G to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 33 as γ-correction data SN, while writing over the previous data and holding the γ-correction data NG_G.

Thus, the reference gradation voltage generation circuit 32 generates reference gradation voltages Y1 to Y256 having a γ characteristic based on the γ-correction data PG_G, and supplies the reference gradation voltages Y1 to Y256 to the DA conversion circuit 34. The reference gradation voltage generation circuit 33 generates reference gradation voltages X1 to X256 having a γ characteristic based on the γ-correction data NG_G, and supplies the reference gradation voltages X1 to X256 to the DA conversion circuit 35. The DA conversion circuit 34 converts display data Q₁ to Q_n corresponding to the aforementioned display data series LD_G into analog positive gradation voltages P₁ to P_n, respectively, on the basis of the reference gradation voltages Y1 to Y256 having the γ characteristic based on the γ-correction data PG_G. The DA conversion circuit 35 converts display data Q₁ to Q_n corresponding to the aforementioned display data series LD_G into analog negative gradation voltages N₁ to N_n, respectively, on the basis of the reference gradation voltages X1 to X256 having the γ characteristic based on the γ-correction data NG_G.

Next, in a horizontal scan period CY3 of the image data signal VDX in which a display data series LD_B is arranged, as shown in FIG. 2, the γ-correction data extraction circuit 21 extracts positive γ-correction data PG_B arranged in the head portion thereof from the image data signal VDX, and supplies the positive γ-correction data PG_B to the γ register 22. In the horizontal scan period CY3, the γ-correction data extraction circuit 23 extracts negative γ-correction data NG_B arranged in the head portion thereof from the image data signal VDX, and supplies the negative γ-correction data NG_B to the γ register 24. Thus, as shown in FIG. 2, the γ register 22 supplies the γ-correction data PG_B to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 32 as γ-correction data SP, while writing over the previous data and holding the γ-correction data PG_B. Also, as shown in FIG. 2, the γ register 24 supplies the γ-correction data NG_B to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 33 as γ-correction data SN, while writing over the previous data and holding the γ-correction data NG_B.

Thus, the reference gradation voltage generation circuit 32 generates reference gradation voltages Y1 to Y256 having a γ characteristic based on the γ-correction data PG_B, and supplies the reference gradation voltages Y1 to Y256 to the DA conversion circuit 34. The reference gradation voltage generation circuit 33 generates reference gradation voltages X1 to X256 having a γ characteristic based on the γ-correction data NG_B, and supplies the reference gradation voltages X1 to X256 to the DA conversion circuit 35. The DA conversion circuit 34 converts display data Q₁ to Q_n corresponding to the aforementioned display data series LD_B into analog positive gradation voltages P₁ to P_n, respectively, on the basis of the reference gradation voltages Y1 to Y256 having the γ characteristic based on the γ-correction data PG_B. The DA conversion circuit 35 converts display data Q₁ to Q_n corresponding to the aforementioned display data series LD_B into analog negative gradation voltages N₁ to N_n, respectively, on the basis of the reference gradation voltages X1 to X256 having the γ characteristic based on the γ-correction data NG_B.

As described above, in the display device 100, as shown in FIG. 2, the drive control unit 11 supplies the data driver 13 with the image data signal VDX in which the γ-correction data PG and NG, which is used when converting the display data PD₁ to PD_n into the positive and negative gradation voltages, are arranged together with the display data PD₁ to PD_n of one horizontal display line in each horizontal scan period H. Therefore, in the γ-correction data transmission unit 130 of the data driver 13, the γ registers 22 and 24 are overwritten with the γ-correction data PG and NG included in the image data signal VDX, respectively, in each horizontal scan period. The gradation voltage conversion unit 132 converts the display data PD₁ to PD_n of one horizontal display line into the positive gradation voltages P₁ to P_n and the negative gradation voltages N₁ to N_n with conversion characteristics based on the γ-correction data PG and NG that has been written in the γ registers 22 and 24, respectively. The drive control unit 11 and the data driver 13 of the display device 100 repeatedly perform such a series of processes.

Accordingly, to generate the positive (negative) gradation voltages P₁ to P_n (N₁ to N_n) in the gradation voltage conversion unit 132, as shown in FIG. 5, only one system of the reference gradation voltage generation circuit (33) that includes the amplifiers (AMP1, AMP2, and AP0 to AP6), the ladder resistors (RD0 to RD160 and R0 to R254), and the γ characteristic regulation circuit (SX) is required.

Therefore, according to the configuration as shown in FIGS. 3 to 5, it is possible to reduce the size of the circuit, as compared with the driver of Patent Document 1 in which gradation voltage generation circuits specific to each of red, green, and blue components (i.e. three systems of gradation voltage generation circuits) are provided.

In the aforementioned embodiments, PG_R and NG_R indicate γ-correction data for a red component, PG_G and NG_G indicate γ-correction data for a green component, and PG_B and NG_B indicate γ-correction data for a blue component. The drive control unit 11 may change the contents itself of each of PG_R, NG_R, PG_G, NG_G, PG_B, and NG_B on a horizontal display line basis. Thus, it is possible to change the setting of the γ characteristic on a horizontal display line (a horizontal scan period) basis.

In the example shown in FIG. 2, the γ-correction data PG and NG corresponding to one of red, green, and blue colors is arranged immediately before the display data series LD of one horizontal display line in each horizontal scan period H of the image data signal VDX, but the γ-correction data PG and NG is not necessarily arranged in every horizontal scan period H.

When there is no vacant time to arrange the γ-correction data PG and NG in each horizontal scan period H of the image data signal VDX, all the γ-correction data PG and NG may be arranged only in the head portion of one vertical scan period.

FIG. 6 is a drawing showing another example of the format of the image data signal VDX generated in consideration of this point. In other words, as shown in FIG. 6, the drive control unit 11 supplies the data driver 13 with the image data signal VDX in which the display data series LD corresponding to one horizontal display line is arranged in each horizontal scan period H and all the γ-correction data PG_R, PG_G, PG_B, NG_R, NG_G, and NG_B are arranged only in the head portion of one vertical scan period V. In this case, the γ-correction data transmission unit 130 of the data driver 13 has the configuration of FIG. 7, instead of the configuration of FIG. 4.

In FIG. 7, a γ-correction data extraction circuit 41 extracts the positive γ-correction data PG_R, PG_G, and PG_B arranged in the head portion of the one vertical scan period V in each vertical scan period V of the image data signal VDX. The γ-correction data extraction circuit 41 supplies the extracted γ-correction data PG_R to a γ register 42, supplies the extracted γ-correction data PG_G to a γ register 43, and supplies the extracted γ-correction data PG_B to a γ register 44. The γ register 42 captures the γ-correction data PG_R supplied by the γ-correction data extraction circuit 41, and, as shown in FIG. 6, supplies the γ-correction data PG_R to a selector 45, while holding the γ-correction data PG_R over the one vertical scan period V. The γ register 43 captures the γ-correction data PG_G supplied by the γ-correction data extraction circuit 41, and, as shown in FIG. 6, supplies the γ-correction data PG_G to the selector 45, while holding the γ-correction data PG_G over the one vertical scan period V. The γ register 44 captures the γ-correction data PG_B supplied by the γ-correction data extraction circuit 41, and, as shown in FIG. 6, supplies the γ-correction data PG_B to the selector 45, while holding the γ-correction data PG_B over the one vertical scan period V. The selector 45 sequentially selects the three pieces of γ-correction data PG_R, PG_G, and PG_B one by one in each horizontal scan period H, and, as shown in FIG. 6, supplies the selected γ-correction data to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 32 as γ-correction data SP.

A γ-correction data extraction circuit 51 extracts the negative γ-correction data NG_R, NG_G, and NG_B arranged in the head portion of the one vertical scan period V in each vertical scan period V of the image data signal VDX. The γ-correction data extraction circuit 51 supplies the extracted γ-correction data NG_R to a γ register 52, supplies the extracted γ-correction data NG_G to a γ register 53, and supplies the extracted γ-correction data NG_B to a γ register 54. The γ register 52 captures the γ-correction data NG_R supplied by the γ-correction data extraction circuit 51, and, as shown in FIG. 6, supplies the γ-correction data NG_R to a selector 55, while holding the γ-correction data NG_R over the one vertical scan period V. The γ register 53 captures the γ-correction data NG_G supplied by the γ-correction data extraction circuit 51, and, as shown in FIG. 6, supplies the γ-correction data NG_G to the selector 55, while holding the γ-correction data NG_G over the one vertical scan period V. The γ register 54 captures the γ-correction data NG_B supplied by the γ-correction data extraction circuit 51, and, as shown in FIG. 6, supplies the γ-correction data NG_B to the selector 55, while holding the γ-correction data NG_B over the one vertical scan period V. The selector 55 sequentially selects the three pieces of γ-correction data NG_R, NG_G, and NG_B one by one in each horizontal scan period H, and, as shown in FIG. 6, supplies the selected γ-correction data to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 33 as γ-correction data SN.

Thus, when the γ-correction data transmission unit 130 has the configuration of FIG. 7, to generate the positive (negative) gradation voltages P₁ to P_n (N₁ to N_n), the selector 45 (55) and the γ register specific to each of red, green, and blue components i.e. three systems of γ registers 42 to 44 (52 to 54) are required.

However, as to the reference gradation voltage generation circuit 32 (33), only one system is required for each polarity, so that it is possible to reduce the size of the circuit, as compared with the driver of Patent Document 1 in which independent three systems of circuits corresponding to three colors of red, green, and blue are required.

In the above-described embodiments, the reference gradation voltage generation circuit 32 (33) is provided with the input amplifiers AMP1 and AMP2 and the first ladder resistor (RD0 to RD160), and a plurality of voltages having different voltage values from each other are supplied to the γ characteristic regulation circuit SX through the respective output taps (a1 to a160) of the first ladder resistor. However, a circuit constituted by the first ladder resistor and the input amplifiers AMP1 and AMP2 may be eliminated, and a voltage group corresponding to the voltages outputted from the plurality of output taps of the circuit may be directly supplied from the outside to the γ characteristic regulation circuit SX.

In the above-described embodiments, the γ-correction data pieces (PG_R, PG_G, PG_B, NG_R, NG_G, and NG_B) are supplied to the data driver 13 in the form of the image data signal VDX, but the γ-correction data may not be included in the image data signal VDX, but may be directly supplied from the outside to the data driver 13. Thus, even when there is insufficient vacant time to arrange the γ-correction data in each horizontal scan period H of the image data signal VDX, the γ-correction data can be rewritten in each horizontal scan period H.

The above-described embodiments describe the configuration and operation of the drive control unit 11 and the data driver 13 by taking a case where the display device 20 is a liquid crystal display panel as an example, but the display device 20 may be, for example, an organic EL (electroluminescence) panel. In this case, the drive control unit 11 supplies the data driver 13 with an image data signal VDX that includes only positive γ-correction data (PG_R, PG_G, and PG_B) as γ-correction data. Furthermore, the organic EL panel eliminates the need for providing the γ-correction data extraction circuit 23 and the γ register 24 included in the γ-correction data transmission unit 130, and eliminates the need for providing the reference gradation voltage generation circuit 33 and the DA conversion circuit 35 included in the gradation voltage conversion unit 132.

In the last analysis, the display driver including the drive control unit 11 and the data driver 13 just needs to include the following gamma correction data transmission unit (130) and gradation voltage conversion unit (32, 34). The gamma correction data transmission unit transmits a plurality of gamma correction data pieces (PG_R, PG_G, PG_B) one by one in each predetermined period (H). The gradation voltage conversion unit converts brightness levels (Q₁ to Q_n) indicated by a video signal into gradation voltages (P₁ to P_n), with a gamma characteristic based on the gamma correction data piece transmitted from the gamma correction data transmission unit. The gamma correction data transmission unit just needs to include the following control unit (11), gamma correction data extraction unit (21, 41), and gamma register (22). The control unit generates an image data signal (VDX) in which a plurality of gamma correction data pieces (PG_R, PG_G, PG_B) are arranged one by one in each horizontal scan period, as well as series of display data pieces (PD₁ to PD_n) indicating the brightness levels of respective display cells (C_R, C_G, C_B) indicated by a video signal (VD) are grouped and arranged on a horizontal scan period basis. The gamma correction data extraction unit sequentially extracts a gamma correction data piece from the image data signal in each horizontal scan period. The gamma register transmits the gamma correction data piece extracted by the gamma correction data extraction unit to the gradation voltage conversion unit, while holding the gamma correction data piece. A gamma correction data transmission unit just needs to include the following control unit (11), gamma correction data extraction unit (41), plurality of gamma registers (42 to 44), and selector (45). The control unit generates an image data signal (VDX) in which a plurality of gamma correction data pieces (PG_R, PG_G, PG_B) are arranged in a head portion of each vertical scan period (V), as well as series of display data pieces (PD₁ to PD_n) indicating the brightness levels of the respective display cells (C_R, C_G, C_B) indicated by a video signal (VD) are grouped and arranged on a horizontal scan period basis. The gamma correction data extraction unit sequentially extracts a plurality of gamma correction data pieces from the image data signal in each vertical scan period. Then, the plurality of gamma registers each hold the plurality of gamma correction data pieces extracted by the gamma correction data extraction unit. The selector selects the gamma correction data pieces held in the respective gamma registers one by one in each horizontal scan period, and transmits the selected gamma correction data piece to the gradation voltage conversion unit.

In the above-described embodiment, the display device 20 in which the n number of display cells C of the same color (either one of red, blue and green) are formed in each of the horizontal display lines S₁ to S_m, as shown in FIG. 1, is driven as a display device. However, instead of the display device 20, a general display device in which three systems of display cells having different display colors (red, blue, or green) from each other are adjacently arranged in a periodic manner in each of the horizontal display lines S₁ to S_m may be driven.

Considering the aforementioned point, FIG. 8 is a block diagram showing another configuration of the display apparatus 100. In the configuration of FIG. 8, the display apparatus 100 includes a drive control unit 11A, a scan driver 12A, and a data driver 13A, which are formed in a semiconductor IC chip, and a display device 20A.

Just as with the display device 20 shown in FIG. 1, the display device 20A includes an m (m is an integer of 2 or more) number of horizontal display lines S₁ to S_m extending in a horizontal direction of a two-dimensional screen and an n (n is an integer of 2 or more) number of data lines D₁ to D_n extending in a vertical direction of the two-dimensional screen. In the display device 20A, a display cell C_R for red display, a display cell C_G for green display, or a display cell C_B for blue display is formed at each of intersections between each horizontal display line and each data line. However, in the display device 20A, just as with general liquid crystal display panels, the display cells are adjacently arranged in a periodic manner in each horizontal display line in order of, for example, the display cells C_R, C_G, and C_B. Therefore, an m number of display cells C_R that correspond to the horizontal display lines S₁ to S_m are formed in each of the data lines D_(3k-2) (k is an integer of 1 or more). An m number of display cells C_G that correspond to the horizontal display lines S₁ to S_m are formed in each of the data lines D_(3k-1). An m number of display cells C_B that correspond to the horizontal display lines S₁ to S_m are formed in each of the data lines D_(3k).

The drive control unit 11A generates an image data signal VDX in a format illustrated in FIG. 9 on the basis of a video signal VD.

Specifically, the drive control unit 11A first calculates a display data piece PD that represents a brightness level of each display cell (C_R, C_G, C_B) as, for example, a 256-step brightness gradation of 8 bits, on the basis of the video signal VD. The drive control unit 11 groups, in each frame of the video signal VD, an (n×m) number of display data pieces PD corresponding to the frame into first to n-th display data groups PX1 to PXn, on the basis of each of the data lines D₁ to D_n. In other words, each of the display data groups PX1 to PXn has a series of display data pieces PD₁ to PD_m corresponding to an m number of display cells C formed at intersections between the data line D corresponding to the display data group PX and each of the horizontal display lines S₁ to S_m. For example, the display data group PX1 has a series of display data pieces PD₁ to PD_m corresponding to an m number of display cells C_R formed at intersections between the data line D₁ and each of the horizontal display lines S₁ to S_m. The display data group PX2 has a series of display data pieces PD₁ to PD_m corresponding to an m number of display cells C_G formed at intersections between the data line D₂ and each of the horizontal display lines S₁ to S_m.

The drive control unit 11A, as shown in FIG. 9, generates the image data signal VDX in which the first to n-th display data groups PX1 to PXn are sequentially arranged in respective data scan periods Tv. Note that the data scan period Tv has such a length that, for example, one vertical scan period of the image data signal VDX is divided by the total number n of the data lines D₁ to D_n. Furthermore, the drive control unit 11A arranges γ-correction data, which is used when displaying each display data group, in each data scan period Tv of the image data signal VDX.

The display data pieces PD₁ to PD_m belonging to the display data groups PX_(3k-2) of the first to n-th display data groups PX1 to PXn are all display data for red display. The display data pieces PD₁ to PD_m belonging to the display data groups PX_(3k-1) are all display data for green display. The display data pieces PD₁ to PD_m belonging to the display data groups PX_(3k) are all display data for blue display. Thus, the drive control unit 11A arranges positive γ-correction data PG_R and negative γ-correction data NG_R, which represent γ correction values for red components, in the data scan periods Tv having the display data groups PX_(3k-2). The drive control unit 11A arranges positive γ-correction data PG_G and negative γ-correction data NG_G, which represent γ correction values for green components, in the data scan periods Tv having the display data groups PX_(3k-1). The drive control unit 11A arranges positive γ-correction data PG_B and negative γ-correction data NG_B, which represent γ correction values for blue components, in the data scan periods Tv having the display data groups PX_(3k).

To be more specific, the γ-correction data (PG_R, NG_R, PG_G, NG_G, PG_B, NG_B) represents information for designating, out of output taps of ladder resistors shown in FIG. 5, a plurality (for example, five) of output taps to perform a conversion corresponding to the γ-correction values.

The drive control unit 11A supplies the image data signal VDX generated as described above to the data driver 13A, while supplying a data scan timing signal to the scan driver 12A in synchronization with a vertical synchronization signal of the video signal VD.

As shown in FIG. 10, the scan driver 12A sequentially and selectively supplies a scan pulse DSP having a voltage Vp to each of the data lines D₁ to D_n of the display device 20A in accordance with the data scan timing signal at intervals of the data scan period Tv.

The data driver 13A converts the m number of display data pieces PD₁ to PD_m contained in the image data signal VDX into gradation voltages G₁ to G_m, which each correspond to the brightness level of the display data piece, in each data scan period Tv, and supplies the gradation voltages G₁ to G_m to the horizontal display lines S₁ to S_m of the display device 20A in synchronization with the scan pulse DSP.

FIG. 11 is a block diagram showing the internal configuration of the data driver 13A. As shown in FIG. 11, the data driver 13A includes a γ-correction data transmission unit 130A, a data capture unit 131A, a gradation voltage conversion unit 132A, and an output unit 133A, instead of the γ-correction data transmission unit 130, the data capture unit 131, the gradation voltage conversion unit 132, and the output unit 133 shown in FIG. 3.

The γ-correction data transmission unit 130A extracts the positive γ-correction data PG_R, PG_G, or PG_B from the image data signal VDX, and supplies the extracted positive γ-correction data to the gradation voltage conversion unit 132A as γ-correction data SP. The γ-correction data transmission unit 130A also extracts the negative γ-correction data NG_R, NG_G, or NG_B from the image data signal VDX, and supplies the extracted negative γ-correction data to the gradation voltage conversion unit 132A as γ-correction data SN.

The data capture unit 131A captures the display data pieces PD₁ to PD_m belonging to the display data group PX from the image data signal VDX in each data scan period Tv, as shown in FIG. 9, and supplies the m number of display data pieces PD₁ to PD_m to the gradation voltage conversion unit 132A as display data pieces Q₁ to Q_m.

The gradation voltage conversion unit 132A converts the display data pieces Q₁ to Q_m into analog positive gradation voltages P₁ to P_m, respectively, in each data scan period Tv with a conversion characteristic based on the positive γ-correction data (PG_R, PG_G, PG_B) included in the image data signal VDX. Furthermore, the gradation voltage conversion unit 132A converts the display data pieces Q₁ to Q_m into analog negative gradation voltages N₁ to N_m, respectively, in each data scan period Tv with a conversion characteristic based on the negative γ-correction data (NG_R, NG_G, NG_B) included in the image data signal VDX. The gradation voltage conversion unit 132A supplies the gradation voltages P₁ to P_m and N₁ to N_m to the output unit 133A.

The output unit 133A alternately selects one of the positive gradation voltages P₁ to P_m and one of the negative gradation voltages N₁ to N_n at predetermined intervals, and supplies the selected gradation voltages to the horizontal display lines S₁ to S_m of the display device 20A as the above-described gradation voltages G₁ to G_m.

FIG. 12 is a block diagram showing an example of the internal configuration of each of the γ-correction data transmission unit 130A and the gradation voltage conversion unit 132A. As shown in FIG. 12, the γ-correction data transmission unit 130A includes a γ-correction data extraction circuit 21A, a γ register 22, a γ-correction data extraction circuit 23A, and a γ register 24.

The γ-correction data extraction circuit 21A extracts the positive γ-correction data PG_R, PG_G, or PG_B from the image data signal VDX, and supplies the extracted γ-correction data PG_R, PG_G, or PG_B to the γ register 22 in each data scan period Tv, as shown in FIG. 9. The γ register 22 writes and holds the γ-correction data PG_R, PG_G, or PG_B supplied from the γ-correction data extraction circuit 21A over previous data. The γ register 22 transmits the one piece of the γ-correction data PG_R, PG_G, or PG_B held as described above, out of the γ-correction data PG_R, PG_G, and PG_B, to the gradation voltage conversion unit 132A over the data scan period Tv, as positive γ-correction data SP.

The γ-correction data extraction circuit 23A extracts negative γ-correction data NG_R, NG_G, or NG_B from the image data signal VDX, and supplies the extracted negative γ-correction data NG_R, NG_G, or NG_B to the γ register 24 in each data scan period Tv as shown in FIG. 9. The γ register 24 writes and holds the γ-correction data NG_R, NG_G, or NG_B supplied from the γ-correction data extraction circuit 23A over previous data. The γ register 24 transmits the one piece of γ-correction data held as described above, out of the γ-correction data NG_R, NG_G, and NG_B, to the gradation voltage conversion unit 132A over the data scan period Tv, as negative γ-correction data SN.

The gradation voltage conversion unit 132A includes reference gradation voltage generation circuits 32 and 33 and DA conversion circuits 34A and 35A.

The reference gradation voltage generation circuit 32 generates reference gradation voltages Y1 to Y256 having γ characteristics based on the γ-correction data SP supplied from the γ-correction data transmission unit 130A, and supplies the reference gradation voltages Y1 to Y256 to the DA conversion circuit 34A. The reference gradation voltage generation circuit 33 generates reference gradation voltages X1 to X256 having γ characteristics based on the γ-correction data SN supplied from the γ-correction data transmission unit 130A, and supplies the reference gradation voltages X1 to X256 to the DA conversion circuit 35A.

Note that, the internal configuration and the operation of each of the reference gradation voltage generation circuits 32 and 33 are the same as those of FIG. 4, and thus a description thereof is omitted.

The DA conversion circuit 34A selects a reference gradation voltage that corresponds to a brightness gradation represented by display data Q of each of the display data pieces Q₁ to Q_m supplied by the data capture unit 131A, from the positive reference gradation voltages Y1 to Y256. The DA conversion circuit 34A outputs each of the gradation voltages Y, which have been selected for each of the display data pieces Q₁ to Q_m as described above, as positive gradation voltages P₁ to P_m. The DA conversion circuit 35A selects a reference gradation voltage that corresponds to a brightness gradation represented by display data Q of each of the display data pieces Q₁ to Q_m supplied by the data capture unit 131A, from the negative reference gradation voltages X1 to X256. The DA conversion circuit 35A outputs each of the gradation voltages X, which have been selected for each of the display data pieces Q₁ to Q_m as described above, as negative gradation voltages N₁ to N_m.

The operation of the configuration of FIG. 12 will be described below with reference to FIG. 9.

First, in a data scan period DS1 of an image data signal VDX in which a display data group PX1 is arranged, as shown in FIG. 9, the γ-correction data extraction circuit 21A of the γ-correction data transmission unit 130A extracts positive γ-correction data PG_R arranged in the head portion thereof from the image data signal VDX, and supplies the positive γ-correction data PG_R to the γ register 22. In the data scan period DS1, the γ-correction data extraction circuit 23A of the γ-correction data transmission unit 130A extracts negative γ-correction data NG_R arranged in the head portion thereof from the image data signal VDX, and supplies the negative γ-correction data NG_R to the γ register 24. Thus, as shown in FIG. 9, the γ register 22 supplies the γ-correction data PG_R to a γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 32 as γ-correction data SP, while holding the γ-correction data PG_R. Also, as shown in FIG. 9, the γ register 24 supplies the γ-correction data NG_R to a γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 33 as γ-correction data SN, while holding the γ-correction data NG_R.

Thus, the reference gradation voltage generation circuit 32 generates reference gradation voltages Y1 to Y256 having γ characteristics based on the γ-correction data PG_R, and supplies the reference gradation voltages Y1 to Y256 to the DA conversion circuit 34A. The reference gradation voltage generation circuit 33 generates reference gradation voltages X1 to X256 having γ characteristics based on the γ-correction data NG_R, and supplies the reference gradation voltages X1 to X256 to the DA conversion circuit 35A. The DA conversion circuit 34A converts each of the display data pieces Q₁ to Q_m corresponding to the above-described display data group PX1 into analog positive gradation voltages P₁ to P_m, respectively, on the basis of the reference gradation voltages Y1 to Y256 having the γ characteristics based on the γ-correction data PG_R. The DA conversion circuit 35A converts each of the display data pieces Q₁ to Q_m corresponding to the above-described display data group PX1 into analog negative gradation voltages N₁ to N_m, respectively, on the basis of the reference gradation voltages X1 to X256 having the γ characteristics based on the γ-correction data NG_R.

Next, in a data scan period DS2 of the image data signal VDX in which a display data group PX2 is arranged, as shown in FIG. 9, the γ-correction data extraction circuit 21A extracts positive γ-correction data PG_G arranged in the head portion thereof from the image data signal VDX, and supplies the positive γ-correction data PG_G to the γ register 22. In the data scan period DS2, the γ-correction data extraction circuit 23A extracts negative γ-correction data NG_G arranged in the head portion thereof from the image data signal VDX, and supplies the negative γ-correction data NG_G to the γ register 24. Thus, as shown in FIG. 9, the γ register 22 supplies the γ-correction data PG_G to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 32 as γ-correction data SP, while overwriting and holding the γ-correction data PG_G. Also, as shown in FIG. 9, the γ register 24 supplies the γ-correction data NG_G to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 33 as γ-correction data SN, while overwriting and holding the γ-correction data NG_G.

Thus, the reference gradation voltage generation circuit 32 generates reference gradation voltages Y1 to Y256 having γ characteristics based on the γ-correction data PG_G, and supplies the reference gradation voltages Y1 to Y256 to the DA conversion circuit 34A. The reference gradation voltage generation circuit 33 generates reference gradation voltages X1 to X256 having γ characteristics based on the γ-correction data NG_G, and supplies the reference gradation voltages X1 to X256 to the DA conversion circuit 35A. The DA conversion circuit 34A converts each of display data pieces Q₁ to Q_m corresponding to the above-described display data group PX2 into analog positive gradation voltages P₁ to P_m, respectively, on the basis of the reference gradation voltages Y1 to Y256 having the γ characteristics based on the γ-correction data PG_G. The DA conversion circuit 35A converts each of the display data pieces Q₁ to Q_m corresponding to the above-described display data group PX2 into analog negative gradation voltages N₁ to N_m, respectively, on the basis of the reference gradation voltages X1 to X256 having the γ characteristics based on the γ-correction data NG_G.

Next, in a data scan period DS3 of the image data signal VDX in which a display data group PX3 is arranged, as shown in FIG. 9, the γ-correction data extraction circuit 21A extracts positive γ-correction data PG_B arranged in the head portion thereof from the image data signal VDX, and supplies the positive γ-correction data PG_B to the γ register 22. In the data scan period DS3, the γ-correction data extraction circuit 23A extracts negative γ-correction data NG_B arranged in the head portion thereof from the image data signal VDX, and supplies the negative γ-correction data NG_B to the γ register 24. Thus, as shown in FIG. 9, the γ register 22 supplies the γ-correction data PG_B to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 32 as γ-correction data SP, while overwriting and holding the γ-correction data PG_B. Also, as shown in FIG. 9, the γ register 24 supplies the γ-correction data NG_B to the γ characteristic regulation circuit SX of the reference gradation voltage generation circuit 33 as γ-correction data SN, while overwriting and holding the γ-correction data NG_B.

Thus, the reference gradation voltage generation circuit 32 generates reference gradation voltages Y1 to Y256 having γ characteristics based on the γ-correction data PG_B, and supplies the reference gradation voltages Y1 to Y256 to the DA conversion circuit 34A. The reference gradation voltage generation circuit 33 generates reference gradation voltages X1 to X256 having γ characteristics based on the γ-correction data NG_B, and supplies the reference gradation voltages X1 to X256 to the DA conversion circuit 35A. The DA conversion circuit 34A converts each of the display data pieces Q₁ to Q_m corresponding to the above-described display data group PX3 into analog positive gradation voltages P₁ to P_m, respectively, on the basis of the reference gradation voltages Y1 to Y256 having the γ characteristics based on the γ-correction data PG_B. The DA conversion circuit 35A converts each of the display data pieces Q₁ to Q_m corresponding to the above-described display data group PX3 into analog negative gradation voltages N₁ to N_m, respectively, on the basis of the reference gradation voltages X1 to X256 having the γ characteristics based on the γ-correction data NG_B.

As described above, in the display device 100, as shown in FIG. 8, the drive control unit 11A supplies the data driver 13A with the image data signal VDX, in which the display data PD₁ to PD_m corresponding to one data line D and the γ-correction data PG and NG used for converting the display data PD₁ to PD_m into the positive and negative gradation voltages are arranged in each data scan period Tv as shown in FIG. 9. Therefore, in the γ-correction data transmission unit 130A of the data driver 13A, the γ registers 22 and 24 are overwritten with the γ-correction data PG and NG contained in the image data signal VDX, respectively, in each data scan period Tv. The gradation voltage conversion unit 132A converts the display data PD₁ to PD_m of one data line into the positive gradation voltages P₁ to P_m and the negative gradation voltages N₁ to N_m with conversion characteristics based on the γ-correction data PG and NG that has been written in the γ registers 22 and 24, respectively. The drive control unit 11 and the data driver 13A of the display device 100 perform a series of processes as described above in a repeated manner.

Accordingly, to generate the positive (negative) gradation voltages P₁ to P_m (N₁ to N_m) in the gradation voltage conversion unit 132A, as shown in FIG. 5, only one system of the reference gradation voltage generation circuit 32 (33) that includes amplifiers (AMP1, AMP2, and AP0 to AP6), ladder resistors (RD0 to RD160 and R0 to R254), and a γ characteristic regulation circuit (SX) is required.

As described above, the configuration of FIG. 8 adopts a drive method in which the data driver 13A supplies the gradation voltages G₁ to G_m to the horizontal display lines S₁ to S_m of the display device 20A, and the scan driver 12A sequentially supplies the scan pulses DSP to the data lines D₁ to D_n. Therefore, even when driving the normal display device in which three systems of display cells having different display colors (red, blue, or green) from each other are adjacently arranged in a periodic manner in each horizontal display line, only one system of the reference gradation voltage generation circuit 32 (33) that is shared among the colors (red, blue, and green) is required, thus allowing a reduction in the size of the circuit, as compared to conventional drivers.

Furthermore, since the configuration of FIG. 8 uses the general display device as the display device 20A, ClearType (trademark) can be used for displaying words, though ClearType is difficult to use when driving the display device 20, as shown in FIG. 1, in which the display cells (C_R, C_G, or C_B) of the same color are arranged in each horizontal display line. ClearType (trademark) is one of anti-aliasing technologies developed by Microsoft Corporation to display fonts as font data. In the ClearType (trademark) technology, for example, the edge of a diagonal line of a letter is represented in units of display cell, instead of in units of pixel constituted of the three display cells (C_R, C_G, and C_B) adjacent to each other.

This application is based on a Japanese Patent Application No. 2016-219527 which is hereby incorporated by reference.

Claims

1. A display driver for supplying a display device having a plurality of display cells with gradation voltages corresponding to brightness levels of the respective display cells indicated by a video signal, wherein the display device includes first to m-th (m is an integer of 2 or more) horizontal display lines each extending in a horizontal direction of the screen, and first to n-th (n is an integer of 2 or more) scan pulse data lines each extending in a vertical direction of the screen so as to intersect the first to m-th horizontal display lines, and the respective display cells located at each intersection of each of the first to m-th horizontal display lines and each of the first to n-th scan pulse data lines, the display driver comprising: and

a scan driver that sequentially and selectively supplies a scan pulse to each of the first to n-th scan pulse data lines; and

a data driver that supplies first to m-th of the gradation voltages corresponding to an m number of the display cells formed in each of the first to n-th scan pulse data lines to the first to m-th horizontal display lines in synchronization with a scan pulse,

wherein the data driver includes a gamma correction data transmission unit that includes: a gamma correction data extraction circuit that receives an image data signal in which a plurality of gamma correction data pieces representing gamma correction values are arranged one by one in each predetermined period, and receives a series of display data pieces indicating the brightness levels of the respective display cells indicated by the video signal are grouped and arranged m-by-m in the predetermined periods, the gamma correction data extraction circuit sequentially extracting the gamma correction data piece from the image data signal in each predetermined period; and a gamma register that holds and transmits the gamma correction data piece extracted by the gamma correction data extraction circuit in each predetermined period; and

wherein the data driver further comprises a gradation voltage conversion unit that generates a plurality of reference gradation voltages with a gamma characteristic based on the gamma correction value indicated by the gamma correction data piece transmitted from the gamma correction data transmission unit.

2. The display driver according to claim 1, wherein an m number of the display cells for displaying the same color as each other are formed in each of the first to n-th scan pulse data lines.

3. A semiconductor device comprising a display driver that is formed therein and supplies a display device having a plurality of display cells with gradation voltages corresponding to brightness levels of the respective display cells indicated by a video signal, wherein the display device includes first to m-th (m is an integer of 2 or more) horizontal display lines each extending in a horizontal direction of the screen, and first to n-th (n is an integer of 2 or more) scan pulse data lines each extending in a vertical direction of the screen so as to intersect the first to m-th horizontal display lines, and the display cell is formed in each of intersections between each of the first to m-th horizontal display lines and each of the first to n-th scan pulse data lines,

the display driver comprising: a scan driver that sequentially and selectively supplies a scan pulse to each of the first to n-th scan pulse data lines; and a data driver that supplies first to m-th of the gradation voltages corresponding to an m number of the display cells formed in each of the first to n-th scan pulse data lines to the first to m-th horizontal display lines in synchronization with the scan pulse,

wherein the data driver includes a gamma correction data transmission unit that includes: a gamma correction data extraction circuit that receives an image data signal in which a plurality of gamma correction data pieces representing gamma correction values are arranged one by one in each predetermined period, and a series of display data pieces indicating the brightness levels of the respective display cells indicated by the video signal are grouped and arranged m-by-m in the predetermined periods, the gamma correction data extraction circuit sequentially extracting the gamma correction data piece from the image data signal in each predetermined period; and a gamma register that holds and transmits the gamma correction data piece extracted by the gamma correction data extraction circuit in each predetermined period; and

wherein the display driver further comprises a gradation voltage conversion unit that generates a plurality of reference gradation voltages with a gamma characteristic based on the gamma correction value indicated by the gamma correction data piece transmitted from the gamma correction data transmission unit.

4. The semiconductor device according to claim 3, wherein an m number of the display cells for displaying the same color as each other are formed in each of the first to n-th scan pulse data lines.

5. The display driver according to claim 1, wherein the predetermined period is a data scan period corresponding to one vertical scan period of the image data signal.

6. The semiconductor device according to claim 3, wherein the predetermined period is a data scan period corresponding to one vertical scan period of the image data signal.